th5/handshake_client.go

1003 рядки
29 KiB
Go

// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
2019-05-12 18:42:15 +01:00
package trs
import (
"bytes"
"crypto"
"crypto/ecdsa"
"crypto/rsa"
"crypto/subtle"
"crypto/x509"
"errors"
"fmt"
"io"
"net"
"strconv"
"strings"
"sync/atomic"
)
type clientHandshakeState struct {
c *Conn
serverHello *serverHelloMsg
hello *clientHelloMsg
suite *cipherSuite
masterSecret []byte
session *ClientSessionState
// TLS 1.0-1.2 fields
finishedHash finishedHash
// TLS 1.3 fields
keySchedule *keySchedule13
privateKey []byte
}
func makeClientHello(config *Config) (*clientHelloMsg, error) {
if len(config.ServerName) == 0 && !config.InsecureSkipVerify {
return nil, errors.New("tls: either ServerName or InsecureSkipVerify must be specified in the tls.Config")
}
nextProtosLength := 0
for _, proto := range config.NextProtos {
if l := len(proto); l == 0 || l > 255 {
return nil, errors.New("tls: invalid NextProtos value")
} else {
nextProtosLength += 1 + l
}
}
if nextProtosLength > 0xffff {
return nil, errors.New("tls: NextProtos values too large")
}
hello := &clientHelloMsg{
vers: config.maxVersion(),
compressionMethods: []uint8{compressionNone},
random: make([]byte, 32),
ocspStapling: true,
scts: true,
serverName: hostnameInSNI(config.ServerName),
supportedCurves: config.curvePreferences(),
supportedPoints: []uint8{pointFormatUncompressed},
nextProtoNeg: len(config.NextProtos) > 0,
secureRenegotiationSupported: true,
delegatedCredential: config.AcceptDelegatedCredential,
alpnProtocols: config.NextProtos,
extendedMSSupported: config.UseExtendedMasterSecret,
}
possibleCipherSuites := config.cipherSuites()
hello.cipherSuites = make([]uint16, 0, len(possibleCipherSuites))
NextCipherSuite:
for _, suiteId := range possibleCipherSuites {
for _, suite := range cipherSuites {
if suite.id != suiteId {
continue
}
// Don't advertise TLS 1.2-only cipher suites unless
// we're attempting TLS 1.2.
if hello.vers < VersionTLS12 && suite.flags&suiteTLS12 != 0 {
continue NextCipherSuite
}
// Don't advertise TLS 1.3-only cipher suites unless
// we're attempting TLS 1.3.
if hello.vers < VersionTLS13 && suite.flags&suiteTLS13 != 0 {
continue NextCipherSuite
}
hello.cipherSuites = append(hello.cipherSuites, suiteId)
continue NextCipherSuite
}
}
_, err := io.ReadFull(config.rand(), hello.random)
if err != nil {
return nil, errors.New("tls: short read from Rand: " + err.Error())
}
if hello.vers >= VersionTLS12 {
hello.supportedSignatureAlgorithms = supportedSignatureAlgorithms
}
if hello.vers >= VersionTLS13 {
// Version preference is indicated via "supported_extensions",
// set legacy_version to TLS 1.2 for backwards compatibility.
hello.vers = VersionTLS12
hello.supportedVersions = config.getSupportedVersions()
hello.supportedSignatureAlgorithms = supportedSignatureAlgorithms13
hello.supportedSignatureAlgorithmsCert = supportedSigAlgorithmsCert(supportedSignatureAlgorithms13)
}
return hello, nil
}
// c.out.Mutex <= L; c.handshakeMutex <= L.
func (c *Conn) clientHandshake() error {
if c.config == nil {
c.config = defaultConfig()
}
// This may be a renegotiation handshake, in which case some fields
// need to be reset.
c.didResume = false
hello, err := makeClientHello(c.config)
if err != nil {
return err
}
if c.handshakes > 0 {
hello.secureRenegotiation = c.clientFinished[:]
}
var session *ClientSessionState
var cacheKey string
sessionCache := c.config.ClientSessionCache
// TLS 1.3 has no session resumption based on session tickets.
if c.config.SessionTicketsDisabled || c.config.maxVersion() >= VersionTLS13 {
sessionCache = nil
}
if sessionCache != nil {
hello.ticketSupported = true
}
// Session resumption is not allowed if renegotiating because
// renegotiation is primarily used to allow a client to send a client
// certificate, which would be skipped if session resumption occurred.
if sessionCache != nil && c.handshakes == 0 {
// Try to resume a previously negotiated TLS session, if
// available.
cacheKey = clientSessionCacheKey(c.conn.RemoteAddr(), c.config)
candidateSession, ok := sessionCache.Get(cacheKey)
if ok {
// Check that the ciphersuite/version used for the
// previous session are still valid.
cipherSuiteOk := false
for _, id := range hello.cipherSuites {
if id == candidateSession.cipherSuite {
cipherSuiteOk = true
break
}
}
versOk := candidateSession.vers >= c.config.minVersion() &&
candidateSession.vers <= c.config.maxVersion()
if versOk && cipherSuiteOk {
session = candidateSession
}
}
}
if session != nil {
hello.sessionTicket = session.sessionTicket
// A random session ID is used to detect when the
// server accepted the ticket and is resuming a session
// (see RFC 5077).
hello.sessionId = make([]byte, 16)
if _, err := io.ReadFull(c.config.rand(), hello.sessionId); err != nil {
return errors.New("tls: short read from Rand: " + err.Error())
}
}
hs := &clientHandshakeState{
c: c,
hello: hello,
session: session,
}
var clientKS keyShare
if c.config.maxVersion() >= VersionTLS13 {
// Create one keyshare for the first default curve. If it is not
// appropriate, the server should raise a HRR.
defaultGroup := c.config.curvePreferences()[0]
hs.privateKey, clientKS, err = c.generateKeyShare(defaultGroup)
if err != nil {
c.sendAlert(alertInternalError)
return err
}
hello.keyShares = []keyShare{clientKS}
// middlebox compatibility mode, provide a non-empty session ID
hello.sessionId = make([]byte, 16)
if _, err := io.ReadFull(c.config.rand(), hello.sessionId); err != nil {
return errors.New("tls: short read from Rand: " + err.Error())
}
}
if err = hs.handshake(); err != nil {
return err
}
// If we had a successful handshake and hs.session is different from
// the one already cached - cache a new one
if sessionCache != nil && hs.session != nil && session != hs.session && c.vers < VersionTLS13 {
sessionCache.Put(cacheKey, hs.session)
}
return nil
}
// Does the handshake, either a full one or resumes old session.
// Requires hs.c, hs.hello, and, optionally, hs.session to be set.
func (hs *clientHandshakeState) handshake() error {
c := hs.c
// send ClientHello
if _, err := c.writeRecord(recordTypeHandshake, hs.hello.marshal()); err != nil {
return err
}
msg, err := c.readHandshake()
if err != nil {
return err
}
var ok bool
if hs.serverHello, ok = msg.(*serverHelloMsg); !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(hs.serverHello, msg)
}
if err = hs.pickTLSVersion(); err != nil {
return err
}
if err = hs.pickCipherSuite(); err != nil {
return err
}
var isResume bool
if c.vers >= VersionTLS13 {
hs.keySchedule = newKeySchedule13(hs.suite, c.config, hs.hello.random)
hs.keySchedule.write(hs.hello.marshal())
hs.keySchedule.write(hs.serverHello.marshal())
} else {
isResume, err = hs.processServerHello()
if err != nil {
return err
}
hs.finishedHash = newFinishedHash(c.vers, hs.suite)
// No signatures of the handshake are needed in a resumption.
// Otherwise, in a full handshake, if we don't have any certificates
// configured then we will never send a CertificateVerify message and
// thus no signatures are needed in that case either.
if isResume || (len(c.config.Certificates) == 0 && c.config.GetClientCertificate == nil) {
hs.finishedHash.discardHandshakeBuffer()
}
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
hs.finishedHash.Write(hs.hello.marshal())
hs.finishedHash.Write(hs.serverHello.marshal())
}
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
c.buffering = true
if c.vers >= VersionTLS13 {
if err := hs.doTLS13Handshake(); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
} else if isResume {
if err := hs.establishKeys(); err != nil {
return err
}
if err := hs.readSessionTicket(); err != nil {
return err
}
if err := hs.readFinished(c.serverFinished[:]); err != nil {
return err
}
c.clientFinishedIsFirst = false
if err := hs.sendFinished(c.clientFinished[:]); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
} else {
if err := hs.doFullHandshake(); err != nil {
return err
}
if err := hs.establishKeys(); err != nil {
return err
}
if err := hs.sendFinished(c.clientFinished[:]); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
c.clientFinishedIsFirst = true
if err := hs.readSessionTicket(); err != nil {
return err
}
if err := hs.readFinished(c.serverFinished[:]); err != nil {
return err
}
}
c.didResume = isResume
c.phase = handshakeConfirmed
atomic.StoreInt32(&c.handshakeConfirmed, 1)
c.handshakeComplete = true
return nil
}
func (hs *clientHandshakeState) pickTLSVersion() error {
Merge branch 'pwu/go-update/master' into pwu/master-merge-upstream Merge upstream go post-1.9 crypto/tls changes from master: d8ee5d11e5 crypto/tls: limit number of consecutive warning alerts 96cd66b266 crypto/tls: advertise support for SHA-512 signatures in 1.2 f265f5db5d archive/zip, crypto/tls: use rand.Read instead of casting ints to bytes 54d04c2fcb crypto/tls: remove bookkeeping code from pHash function d1bbdbe760 crypto/tls: replace signatureAndHash by SignatureScheme. cb3b345209 crypto/tls: fix first byte test for 255 CBC padding bytes d153df8e4b all: revert "all: prefer strings.LastIndexByte over strings.LastIndex" 5e42658fc0 all: prefer bytes.IndexByte over bytes.Index d2826d3e06 all: prefer strings.LastIndexByte over strings.LastIndex 5a986eca86 all: fix article typos 0f9a2cf2c4 crypto/tls: fix clientHelloMsg fuzzer not to generate the RI SCSV e7d46cee2f crypto/tls: fix and expand TestVerifyPeerCertificate and TestGetClientCertificate 85deaf6077 crypto/tls: fix docstring of Config.ClientSessionCache 4a5f85babb crypto/tls: disallow handshake messages fragmented across CCS b3465646ff crypto/tls: add BenchmarkHandshakeServer d38d357c78 crypto/tls: don't check whether an ec point is on a curve twice e085a891f0 crypto/tls: split clientHandshake into multiple methods Conflicts: * handshake_client.go: conflict between our ("crypto/tls: allow client to pick TLS 1.3, do not enable it by default.") and upstream ("crypto/tls: split clientHandshake into multiple methods"), resolve by applying the mutualVersion->pickVersion change in pickTLSVersion. * handshake_server.go: trivial conflict due to upstreamed patch ("crypto/tls: replace signatureAndHash by SignatureScheme.") and ("crypto/tls: implement TLS 1.3 server 0-RTT") which added pskBinder. Other merge changes: * tls13.go: signatureAndHashes as added in ("crypto/tls: implement TLS 1.3 minimal server") was renamed as required by ("crypto/tls: replace signatureAndHash by SignatureScheme."). * handshake_client.go: moved check from ("crypto/tls: check that client cipher suite matches version") to pickCipherSuite as required by ("crypto/tls: split clientHandshake into multiple methods").
2017-11-14 13:58:35 +00:00
vers, ok := hs.c.config.pickVersion([]uint16{hs.serverHello.vers})
if !ok || vers < VersionTLS10 {
// TLS 1.0 is the minimum version supported as a client.
hs.c.sendAlert(alertProtocolVersion)
return fmt.Errorf("tls: server selected unsupported protocol version %x", hs.serverHello.vers)
}
hs.c.vers = vers
hs.c.haveVers = true
return nil
}
func (hs *clientHandshakeState) pickCipherSuite() error {
if hs.suite = mutualCipherSuite(hs.hello.cipherSuites, hs.serverHello.cipherSuite); hs.suite == nil {
hs.c.sendAlert(alertHandshakeFailure)
return errors.New("tls: server chose an unconfigured cipher suite")
}
Merge branch 'pwu/go-update/master' into pwu/master-merge-upstream Merge upstream go post-1.9 crypto/tls changes from master: d8ee5d11e5 crypto/tls: limit number of consecutive warning alerts 96cd66b266 crypto/tls: advertise support for SHA-512 signatures in 1.2 f265f5db5d archive/zip, crypto/tls: use rand.Read instead of casting ints to bytes 54d04c2fcb crypto/tls: remove bookkeeping code from pHash function d1bbdbe760 crypto/tls: replace signatureAndHash by SignatureScheme. cb3b345209 crypto/tls: fix first byte test for 255 CBC padding bytes d153df8e4b all: revert "all: prefer strings.LastIndexByte over strings.LastIndex" 5e42658fc0 all: prefer bytes.IndexByte over bytes.Index d2826d3e06 all: prefer strings.LastIndexByte over strings.LastIndex 5a986eca86 all: fix article typos 0f9a2cf2c4 crypto/tls: fix clientHelloMsg fuzzer not to generate the RI SCSV e7d46cee2f crypto/tls: fix and expand TestVerifyPeerCertificate and TestGetClientCertificate 85deaf6077 crypto/tls: fix docstring of Config.ClientSessionCache 4a5f85babb crypto/tls: disallow handshake messages fragmented across CCS b3465646ff crypto/tls: add BenchmarkHandshakeServer d38d357c78 crypto/tls: don't check whether an ec point is on a curve twice e085a891f0 crypto/tls: split clientHandshake into multiple methods Conflicts: * handshake_client.go: conflict between our ("crypto/tls: allow client to pick TLS 1.3, do not enable it by default.") and upstream ("crypto/tls: split clientHandshake into multiple methods"), resolve by applying the mutualVersion->pickVersion change in pickTLSVersion. * handshake_server.go: trivial conflict due to upstreamed patch ("crypto/tls: replace signatureAndHash by SignatureScheme.") and ("crypto/tls: implement TLS 1.3 server 0-RTT") which added pskBinder. Other merge changes: * tls13.go: signatureAndHashes as added in ("crypto/tls: implement TLS 1.3 minimal server") was renamed as required by ("crypto/tls: replace signatureAndHash by SignatureScheme."). * handshake_client.go: moved check from ("crypto/tls: check that client cipher suite matches version") to pickCipherSuite as required by ("crypto/tls: split clientHandshake into multiple methods").
2017-11-14 13:58:35 +00:00
// Check that the chosen cipher suite matches the protocol version.
if hs.c.vers >= VersionTLS13 && hs.suite.flags&suiteTLS13 == 0 ||
hs.c.vers < VersionTLS13 && hs.suite.flags&suiteTLS13 != 0 {
hs.c.sendAlert(alertHandshakeFailure)
return errors.New("tls: server chose an inappropriate cipher suite")
}
hs.c.cipherSuite = hs.suite.id
return nil
}
// processCertsFromServer takes a chain of server certificates from a
// Certificate message and verifies them.
func (hs *clientHandshakeState) processCertsFromServer(certificates [][]byte) error {
c := hs.c
certs := make([]*x509.Certificate, len(certificates))
for i, asn1Data := range certificates {
cert, err := x509.ParseCertificate(asn1Data)
if err != nil {
c.sendAlert(alertBadCertificate)
return errors.New("tls: failed to parse certificate from server: " + err.Error())
}
certs[i] = cert
}
if !c.config.InsecureSkipVerify {
opts := x509.VerifyOptions{
Roots: c.config.RootCAs,
CurrentTime: c.config.time(),
DNSName: c.config.ServerName,
Intermediates: x509.NewCertPool(),
}
for i, cert := range certs {
if i == 0 {
continue
}
opts.Intermediates.AddCert(cert)
}
var err error
c.verifiedChains, err = certs[0].Verify(opts)
if err != nil {
c.sendAlert(alertBadCertificate)
return err
}
}
if c.config.VerifyPeerCertificate != nil {
if err := c.config.VerifyPeerCertificate(certificates, c.verifiedChains); err != nil {
c.sendAlert(alertBadCertificate)
return err
}
}
switch certs[0].PublicKey.(type) {
case *rsa.PublicKey, *ecdsa.PublicKey:
break
default:
c.sendAlert(alertUnsupportedCertificate)
return fmt.Errorf("tls: server's certificate contains an unsupported type of public key: %T", certs[0].PublicKey)
}
c.peerCertificates = certs
return nil
}
// processDelegatedCredentialFromServer unmarshals the delegated credential
// offered by the server (if present) and validates it using the peer
// certificate and the signature scheme (`scheme`) indicated by the server in
// the "signature_scheme" extension.
func (hs *clientHandshakeState) processDelegatedCredentialFromServer(serialized []byte, scheme SignatureScheme) error {
c := hs.c
var dc *delegatedCredential
var err error
if serialized != nil {
// Assert that the DC extension was indicated by the client.
if !hs.hello.delegatedCredential {
c.sendAlert(alertUnexpectedMessage)
return errors.New("tls: got delegated credential extension without indication")
}
// Parse the delegated credential.
dc, err = unmarshalDelegatedCredential(serialized)
if err != nil {
c.sendAlert(alertDecodeError)
return fmt.Errorf("tls: delegated credential: %s", err)
}
}
if dc != nil && !c.config.InsecureSkipVerify {
if v, err := dc.validate(c.peerCertificates[0], c.config.time()); err != nil {
c.sendAlert(alertIllegalParameter)
return fmt.Errorf("delegated credential: %s", err)
} else if !v {
c.sendAlert(alertIllegalParameter)
return errors.New("delegated credential: signature invalid")
} else if dc.cred.expectedVersion != hs.c.vers {
c.sendAlert(alertIllegalParameter)
return errors.New("delegated credential: protocol version mismatch")
} else if dc.cred.expectedCertVerifyAlgorithm != scheme {
c.sendAlert(alertIllegalParameter)
return errors.New("delegated credential: signature scheme mismatch")
}
}
c.verifiedDc = dc
return nil
}
func (hs *clientHandshakeState) doFullHandshake() error {
c := hs.c
msg, err := c.readHandshake()
if err != nil {
return err
}
certMsg, ok := msg.(*certificateMsg)
if !ok || len(certMsg.certificates) == 0 {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certMsg, msg)
}
hs.finishedHash.Write(certMsg.marshal())
if c.handshakes == 0 {
// If this is the first handshake on a connection, process and
// (optionally) verify the server's certificates.
if err := hs.processCertsFromServer(certMsg.certificates); err != nil {
return err
}
} else {
// This is a renegotiation handshake. We require that the
// server's identity (i.e. leaf certificate) is unchanged and
// thus any previous trust decision is still valid.
//
// See https://mitls.org/pages/attacks/3SHAKE for the
// motivation behind this requirement.
if !bytes.Equal(c.peerCertificates[0].Raw, certMsg.certificates[0]) {
c.sendAlert(alertBadCertificate)
return errors.New("tls: server's identity changed during renegotiation")
}
}
msg, err = c.readHandshake()
if err != nil {
return err
}
cs, ok := msg.(*certificateStatusMsg)
if ok {
// RFC4366 on Certificate Status Request:
// The server MAY return a "certificate_status" message.
if !hs.serverHello.ocspStapling {
// If a server returns a "CertificateStatus" message, then the
// server MUST have included an extension of type "status_request"
// with empty "extension_data" in the extended server hello.
c.sendAlert(alertUnexpectedMessage)
return errors.New("tls: received unexpected CertificateStatus message")
}
hs.finishedHash.Write(cs.marshal())
if cs.statusType == statusTypeOCSP {
c.ocspResponse = cs.response
}
msg, err = c.readHandshake()
if err != nil {
return err
}
}
keyAgreement := hs.suite.ka(c.vers)
// Set the public key used to verify the handshake.
pk := c.peerCertificates[0].PublicKey
skx, ok := msg.(*serverKeyExchangeMsg)
if ok {
hs.finishedHash.Write(skx.marshal())
err = keyAgreement.processServerKeyExchange(c.config, hs.hello, hs.serverHello, pk, skx)
if err != nil {
c.sendAlert(alertUnexpectedMessage)
return err
}
msg, err = c.readHandshake()
if err != nil {
return err
}
}
var chainToSend *Certificate
var certRequested bool
certReq, ok := msg.(*certificateRequestMsg)
if ok {
certRequested = true
hs.finishedHash.Write(certReq.marshal())
if chainToSend, err = hs.getCertificate(certReq); err != nil {
c.sendAlert(alertInternalError)
return err
}
msg, err = c.readHandshake()
if err != nil {
return err
}
}
shd, ok := msg.(*serverHelloDoneMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(shd, msg)
}
hs.finishedHash.Write(shd.marshal())
// If the server requested a certificate then we have to send a
// Certificate message, even if it's empty because we don't have a
// certificate to send.
if certRequested {
certMsg = new(certificateMsg)
certMsg.certificates = chainToSend.Certificate
hs.finishedHash.Write(certMsg.marshal())
if _, err := c.writeRecord(recordTypeHandshake, certMsg.marshal()); err != nil {
return err
}
}
preMasterSecret, ckx, err := keyAgreement.generateClientKeyExchange(c.config, hs.hello, pk)
if err != nil {
c.sendAlert(alertInternalError)
return err
}
if ckx != nil {
hs.finishedHash.Write(ckx.marshal())
if _, err := c.writeRecord(recordTypeHandshake, ckx.marshal()); err != nil {
return err
}
}
c.useEMS = hs.serverHello.extendedMSSupported
hs.masterSecret = masterFromPreMasterSecret(c.vers, hs.suite, preMasterSecret, hs.hello.random, hs.serverHello.random, hs.finishedHash, c.useEMS)
if err := c.config.writeKeyLog("CLIENT_RANDOM", hs.hello.random, hs.masterSecret); err != nil {
c.sendAlert(alertInternalError)
return errors.New("tls: failed to write to key log: " + err.Error())
}
if chainToSend != nil && len(chainToSend.Certificate) > 0 {
certVerify := &certificateVerifyMsg{
hasSignatureAndHash: c.vers >= VersionTLS12,
}
key, ok := chainToSend.PrivateKey.(crypto.Signer)
if !ok {
c.sendAlert(alertInternalError)
return fmt.Errorf("tls: client certificate private key of type %T does not implement crypto.Signer", chainToSend.PrivateKey)
}
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
signatureAlgorithm, sigType, hashFunc, err := pickSignatureAlgorithm(key.Public(), certReq.supportedSignatureAlgorithms, hs.hello.supportedSignatureAlgorithms, c.vers)
if err != nil {
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
c.sendAlert(alertInternalError)
return err
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
}
// SignatureAndHashAlgorithm was introduced in TLS 1.2.
if certVerify.hasSignatureAndHash {
certVerify.signatureAlgorithm = signatureAlgorithm
}
digest, err := hs.finishedHash.hashForClientCertificate(sigType, hashFunc, hs.masterSecret)
if err != nil {
c.sendAlert(alertInternalError)
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
return err
}
signOpts := crypto.SignerOpts(hashFunc)
if sigType == signatureRSAPSS {
signOpts = &rsa.PSSOptions{SaltLength: rsa.PSSSaltLengthEqualsHash, Hash: hashFunc}
}
certVerify.signature, err = key.Sign(c.config.rand(), digest, signOpts)
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
if err != nil {
c.sendAlert(alertInternalError)
return err
}
hs.finishedHash.Write(certVerify.marshal())
if _, err := c.writeRecord(recordTypeHandshake, certVerify.marshal()); err != nil {
return err
}
}
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
hs.finishedHash.discardHandshakeBuffer()
return nil
}
func (hs *clientHandshakeState) establishKeys() error {
c := hs.c
clientMAC, serverMAC, clientKey, serverKey, clientIV, serverIV :=
crypto/tls: decouple handshake signatures from the handshake hash. Prior to TLS 1.2, the handshake had a pleasing property that one could incrementally hash it and, from that, get the needed hashes for both the CertificateVerify and Finished messages. TLS 1.2 introduced negotiation for the signature and hash and it became possible for the handshake hash to be, say, SHA-384, but for the CertificateVerify to sign the handshake with SHA-1. The problem is that one doesn't know in advance which hashes will be needed and thus the handshake needs to be buffered. Go ignored this, always kept a single handshake hash, and any signatures over the handshake had to use that hash. However, there are a set of servers that inspect the client's offered signature hash functions and will abort the handshake if one of the server's certificates is signed with a hash function outside of that set. https://robertsspaceindustries.com/ is an example of such a server. Clearly not a lot of thought happened when that server code was written, but its out there and we have to deal with it. This change decouples the handshake hash from the CertificateVerify hash. This lays the groundwork for advertising support for SHA-384 but doesn't actually make that change in the interests of reviewability. Updating the advertised hash functions will cause changes in many of the testdata/ files and some errors might get lost in the noise. This change only needs to update four testdata/ files: one because a SHA-384-based handshake is now being signed with SHA-256 and the others because the TLS 1.2 CertificateRequest message now includes SHA-1. This change also has the effect of adding support for client-certificates in SSLv3 servers. However, SSLv3 is now disabled by default so this should be moot. It would be possible to avoid much of this change and just support SHA-384 for the ServerKeyExchange as the SKX only signs over the nonces and SKX params (a design mistake in TLS). However, that would leave Go in the odd situation where it advertised support for SHA-384, but would only use the handshake hash when signing client certificates. I fear that'll just cause problems in the future. Much of this code was written by davidben@ for the purposes of testing BoringSSL. Partly addresses #9757 Change-Id: I5137a472b6076812af387a5a69fc62c7373cd485 Reviewed-on: https://go-review.googlesource.com/9415 Run-TryBot: Adam Langley <agl@golang.org> Reviewed-by: Adam Langley <agl@golang.org>
2015-04-28 17:13:38 +01:00
keysFromMasterSecret(c.vers, hs.suite, hs.masterSecret, hs.hello.random, hs.serverHello.random, hs.suite.macLen, hs.suite.keyLen, hs.suite.ivLen)
var clientCipher, serverCipher interface{}
var clientHash, serverHash macFunction
if hs.suite.cipher != nil {
clientCipher = hs.suite.cipher(clientKey, clientIV, false /* not for reading */)
clientHash = hs.suite.mac(c.vers, clientMAC)
serverCipher = hs.suite.cipher(serverKey, serverIV, true /* for reading */)
serverHash = hs.suite.mac(c.vers, serverMAC)
} else {
clientCipher = hs.suite.aead(clientKey, clientIV)
serverCipher = hs.suite.aead(serverKey, serverIV)
}
c.in.prepareCipherSpec(c.vers, serverCipher, serverHash)
c.out.prepareCipherSpec(c.vers, clientCipher, clientHash)
return nil
}
func (hs *clientHandshakeState) serverResumedSession() bool {
// If the server responded with the same sessionId then it means the
// sessionTicket is being used to resume a TLS session.
return hs.session != nil && hs.hello.sessionId != nil &&
bytes.Equal(hs.serverHello.sessionId, hs.hello.sessionId)
}
func (hs *clientHandshakeState) processServerHello() (bool, error) {
c := hs.c
if hs.serverHello.compressionMethod != compressionNone {
c.sendAlert(alertUnexpectedMessage)
return false, errors.New("tls: server selected unsupported compression format")
}
if c.handshakes == 0 && hs.serverHello.secureRenegotiationSupported {
c.secureRenegotiation = true
if len(hs.serverHello.secureRenegotiation) != 0 {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: initial handshake had non-empty renegotiation extension")
}
}
if c.handshakes > 0 && c.secureRenegotiation {
var expectedSecureRenegotiation [24]byte
copy(expectedSecureRenegotiation[:], c.clientFinished[:])
copy(expectedSecureRenegotiation[12:], c.serverFinished[:])
if !bytes.Equal(hs.serverHello.secureRenegotiation, expectedSecureRenegotiation[:]) {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: incorrect renegotiation extension contents")
}
}
if hs.serverHello.extendedMSSupported {
if hs.hello.extendedMSSupported {
c.useEMS = true
} else {
// server wants to calculate master secret in a different way than client
c.sendAlert(alertUnsupportedExtension)
return false, errors.New("tls: unexpected extension (EMS) received in SH")
}
}
clientDidNPN := hs.hello.nextProtoNeg
clientDidALPN := len(hs.hello.alpnProtocols) > 0
serverHasNPN := hs.serverHello.nextProtoNeg
serverHasALPN := len(hs.serverHello.alpnProtocol) > 0
if !clientDidNPN && serverHasNPN {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: server advertised unrequested NPN extension")
}
if !clientDidALPN && serverHasALPN {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: server advertised unrequested ALPN extension")
}
if serverHasNPN && serverHasALPN {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: server advertised both NPN and ALPN extensions")
}
if serverHasALPN {
c.clientProtocol = hs.serverHello.alpnProtocol
c.clientProtocolFallback = false
}
c.scts = hs.serverHello.scts
if !hs.serverResumedSession() {
return false, nil
}
if hs.session.useEMS != c.useEMS {
return false, errors.New("differing EMS state")
}
if hs.session.vers != c.vers {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: server resumed a session with a different version")
}
if hs.session.cipherSuite != hs.suite.id {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: server resumed a session with a different cipher suite")
}
// Restore masterSecret and peerCerts from previous state
hs.masterSecret = hs.session.masterSecret
c.peerCertificates = hs.session.serverCertificates
c.verifiedChains = hs.session.verifiedChains
return true, nil
}
func (hs *clientHandshakeState) readFinished(out []byte) error {
c := hs.c
c.readRecord(recordTypeChangeCipherSpec)
if c.in.err != nil {
return c.in.err
}
msg, err := c.readHandshake()
if err != nil {
return err
}
serverFinished, ok := msg.(*finishedMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(serverFinished, msg)
}
verify := hs.finishedHash.serverSum(hs.masterSecret)
if len(verify) != len(serverFinished.verifyData) ||
subtle.ConstantTimeCompare(verify, serverFinished.verifyData) != 1 {
c.sendAlert(alertDecryptError)
return errors.New("tls: server's Finished message was incorrect")
}
hs.finishedHash.Write(serverFinished.marshal())
copy(out, verify)
return nil
}
func (hs *clientHandshakeState) readSessionTicket() error {
if !hs.serverHello.ticketSupported {
return nil
}
c := hs.c
msg, err := c.readHandshake()
if err != nil {
return err
}
sessionTicketMsg, ok := msg.(*newSessionTicketMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(sessionTicketMsg, msg)
}
hs.finishedHash.Write(sessionTicketMsg.marshal())
hs.session = &ClientSessionState{
sessionTicket: sessionTicketMsg.ticket,
vers: c.vers,
cipherSuite: hs.suite.id,
masterSecret: hs.masterSecret,
serverCertificates: c.peerCertificates,
verifiedChains: c.verifiedChains,
useEMS: c.useEMS,
}
return nil
}
func (hs *clientHandshakeState) sendFinished(out []byte) error {
c := hs.c
if _, err := c.writeRecord(recordTypeChangeCipherSpec, []byte{1}); err != nil {
return err
}
if hs.serverHello.nextProtoNeg {
nextProto := new(nextProtoMsg)
proto, fallback := mutualProtocol(c.config.NextProtos, hs.serverHello.nextProtos)
nextProto.proto = proto
c.clientProtocol = proto
c.clientProtocolFallback = fallback
hs.finishedHash.Write(nextProto.marshal())
if _, err := c.writeRecord(recordTypeHandshake, nextProto.marshal()); err != nil {
return err
}
}
finished := new(finishedMsg)
finished.verifyData = hs.finishedHash.clientSum(hs.masterSecret)
hs.finishedHash.Write(finished.marshal())
if _, err := c.writeRecord(recordTypeHandshake, finished.marshal()); err != nil {
return err
}
copy(out, finished.verifyData)
return nil
}
// tls11SignatureSchemes contains the signature schemes that we synthesise for
// a TLS <= 1.1 connection, based on the supported certificate types.
var tls11SignatureSchemes = []SignatureScheme{ECDSAWithP256AndSHA256, ECDSAWithP384AndSHA384, ECDSAWithP521AndSHA512, PKCS1WithSHA256, PKCS1WithSHA384, PKCS1WithSHA512, PKCS1WithSHA1}
const (
// tls11SignatureSchemesNumECDSA is the number of initial elements of
// tls11SignatureSchemes that use ECDSA.
tls11SignatureSchemesNumECDSA = 3
// tls11SignatureSchemesNumRSA is the number of trailing elements of
// tls11SignatureSchemes that use RSA.
tls11SignatureSchemesNumRSA = 4
)
func (hs *clientHandshakeState) getCertificate(certReq *certificateRequestMsg) (*Certificate, error) {
c := hs.c
var rsaAvail, ecdsaAvail bool
for _, certType := range certReq.certificateTypes {
switch certType {
case certTypeRSASign:
rsaAvail = true
case certTypeECDSASign:
ecdsaAvail = true
}
}
if c.config.GetClientCertificate != nil {
var signatureSchemes []SignatureScheme
if !certReq.hasSignatureAndHash {
// Prior to TLS 1.2, the signature schemes were not
// included in the certificate request message. In this
// case we use a plausible list based on the acceptable
// certificate types.
signatureSchemes = tls11SignatureSchemes
if !ecdsaAvail {
signatureSchemes = signatureSchemes[tls11SignatureSchemesNumECDSA:]
}
if !rsaAvail {
signatureSchemes = signatureSchemes[:len(signatureSchemes)-tls11SignatureSchemesNumRSA]
}
} else {
signatureSchemes = certReq.supportedSignatureAlgorithms
}
return c.config.GetClientCertificate(&CertificateRequestInfo{
AcceptableCAs: certReq.certificateAuthorities,
SignatureSchemes: signatureSchemes,
})
}
// RFC 4346 on the certificateAuthorities field: A list of the
// distinguished names of acceptable certificate authorities.
// These distinguished names may specify a desired
// distinguished name for a root CA or for a subordinate CA;
// thus, this message can be used to describe both known roots
// and a desired authorization space. If the
// certificate_authorities list is empty then the client MAY
// send any certificate of the appropriate
// ClientCertificateType, unless there is some external
// arrangement to the contrary.
// We need to search our list of client certs for one
// where SignatureAlgorithm is acceptable to the server and the
// Issuer is in certReq.certificateAuthorities
findCert:
for i, chain := range c.config.Certificates {
if !rsaAvail && !ecdsaAvail {
continue
}
for j, cert := range chain.Certificate {
x509Cert := chain.Leaf
// parse the certificate if this isn't the leaf
// node, or if chain.Leaf was nil
if j != 0 || x509Cert == nil {
var err error
if x509Cert, err = x509.ParseCertificate(cert); err != nil {
c.sendAlert(alertInternalError)
return nil, errors.New("tls: failed to parse client certificate #" + strconv.Itoa(i) + ": " + err.Error())
}
}
switch {
case rsaAvail && x509Cert.PublicKeyAlgorithm == x509.RSA:
case ecdsaAvail && x509Cert.PublicKeyAlgorithm == x509.ECDSA:
default:
continue findCert
}
if len(certReq.certificateAuthorities) == 0 {
// they gave us an empty list, so just take the
// first cert from c.config.Certificates
return &chain, nil
}
for _, ca := range certReq.certificateAuthorities {
if bytes.Equal(x509Cert.RawIssuer, ca) {
return &chain, nil
}
}
}
}
// No acceptable certificate found. Don't send a certificate.
return new(Certificate), nil
}
// clientSessionCacheKey returns a key used to cache sessionTickets that could
// be used to resume previously negotiated TLS sessions with a server.
func clientSessionCacheKey(serverAddr net.Addr, config *Config) string {
if len(config.ServerName) > 0 {
return config.ServerName
}
return serverAddr.String()
}
// mutualProtocol finds the mutual Next Protocol Negotiation or ALPN protocol
// given list of possible protocols and a list of the preference order. The
// first list must not be empty. It returns the resulting protocol and flag
// indicating if the fallback case was reached.
func mutualProtocol(protos, preferenceProtos []string) (string, bool) {
for _, s := range preferenceProtos {
for _, c := range protos {
if s == c {
return s, false
}
}
}
return protos[0], true
}
2017-07-03 15:24:46 +01:00
// hostnameInSNI converts name into an appropriate hostname for SNI.
// Literal IP addresses and absolute FQDNs are not permitted as SNI values.
// See https://tools.ietf.org/html/rfc6066#section-3.
func hostnameInSNI(name string) string {
host := name
if len(host) > 0 && host[0] == '[' && host[len(host)-1] == ']' {
host = host[1 : len(host)-1]
}
if i := strings.LastIndex(host, "%"); i > 0 {
host = host[:i]
}
if net.ParseIP(host) != nil {
return ""
}
for len(name) > 0 && name[len(name)-1] == '.' {
name = name[:len(name)-1]
}
return name
}